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Heterogeneous abnormalities of in-vivo left ventricular calcium influx and function in mouse models of muscular dystrophy cardiomyopathy. PDF

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Preview Heterogeneous abnormalities of in-vivo left ventricular calcium influx and function in mouse models of muscular dystrophy cardiomyopathy.

Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 http://jcmr-online.com/content/15/1/4 RESEARCH Open Access Heterogeneous abnormalities of in-vivo left ventricular calcium influx and function in mouse models of muscular dystrophy cardiomyopathy Elizabeth Greally1, Benjamin J Davison1, Alison Blain1, Steve Laval1, Andrew Blamire2, Volker Straub1 and Guy A MacGowan1,3* Abstract Background: Manganese-enhanced cardiovascular magnetic resonance (MECMR) can non-invasively assess myocardial calcium influx, and calcium levels are known to be elevated in muscular dystrophy cardiomyopathy based oncellularstudies. Methods: Left ventricular functional studies and MECMR were performed in mdx mice (model of Duchenne Muscular Dystrophy, 24 and 40 weeks)and Sgcd−/− mice (Limb Girdle Muscular Dystrophy2 F, 16 and 32 weeks), compared to wild typecontrols(C57Bl/10, WT). Results: Both models had leftventricular hypertrophy atthe later age compared to WT, though the mdx mice had reduced stroke volumes and the Sgcd−/− mice increased heart rate and cardiac index. Especially atthe younger ages, MECMR was significantly elevated inboth models (both P<0.05 versusWT). The L-type calcium channel inhibitor diltiazem (5mg/kgi.p.) significantly reduced MECMRinthe mdx mice (P<0.01),though only witha higher dose (10 mg/kg i.p.) in theSgcd−/−mice (P<0.05). As theSgcd−/− mice had increased heart rates, to determine the roleof heart rate inMECMR westudied the hyperpolarization-activated cyclic nucleotide-gated channelinhibitor ZD7288 which selectivelyreduces heart rate.This reduced heart rate and MECMRinall mouse groups. However, when looking atthe time course of reduction of MECMRinthe Sgcd−/− mice atup to 5minutes ofthe manganese infusion when heart rates were matched to theWT mice, MECMRwas still significantlyelevated in the Sgcd−/− mice (P<0.01)indicating that heart rate alone could notaccount for all theincreased MECMR. Conclusions: Despite both mouse models exhibiting increased in-vivocalcium influx at anearly stagein the development of thecardiomyopathy before leftventricular hypertrophy, thereare distinct phenotypical differences between the 2models interms of heart rates, hemodynamics and responses to calcium channel inhibitors. Keywords: Muscular dystrophy, Cardiomyopathy, Magnetic resonance imaging, Calcium Background autosomal recessive limb girdle muscular dystrophies Muscular dystrophies arefrequently associated with cardi- (LGMD2C-F), and these also frequently have dilated car- omyopathies. In Duchenne muscular dystrophy (DMD), diomyopathy, especially those patients with LGMD2F which is caused by the absence of dystrophin, either clin- causedbymutationsintheδ-sarcoglycangene[3]. ical or subclinical dilated cardiomyopathy is invariably Ahypothesistoexplaintheunderlyingpathophysiology present [1,2]. Recessive mutations in one of the genes for of cardiomyopathies associated with muscular dystrophy α-, β-, γ- or δ-sarcoglycan causeaheterogeneous group of is that recurrent membrane injury leads to an increased influx of calcium [4] which then causes downstream *Correspondence:[email protected] effects such as activation of calcium-dependent hyper- 1InstituteofGeneticMedicine,NewcastleUniversity,InternationalCenterfor trophic pathways [5], reactive oxygen species [6] and cell Life,Newcastle,UK 3DeptofCardiology,FreemanHospitalandNewcastleUniversity,Newcastle death through necrosis with mitochondrial defects [7]. uponTyneNE77DN,UK Membrane injury may not be the only mechanism Fulllistofauthorinformationisavailableattheendofthearticle ©2013Greallyetal.;licenseeBioMedCentralLtd.ThisisanOpenAccessarticledistributedunderthetermsoftheCreative CommonsAttributionLicense(http://creativecommons.org/licenses/by/2.0),whichpermitsunrestricteduse,distribution,and reproductioninanymedium,providedtheoriginalworkisproperlycited. Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page2of8 http://jcmr-online.com/content/15/1/4 whereby calcium enters cardiomyocytes. Cohn et al. [8] of 0.5 L/min. The tail-vein was cannulated and mice have shown that the L-type calcium channel antagonist placed on a MR compatible sled with surface ECG elec- verapamil restores left ventricular function in Sgcd−/− trodes on the chest wall, respiration pillow and cutane- mice, though has no effects in mdx mice. Whereas this ous temperature probe (Dazai Research Instruments, wasexplainedatthattimeonthebasisofeffectsoncoron- MICe, Toronto, Canada). This was connected to MR aryvasculature,subsequentstudieshavesuggestedthatthis compatible monitoring equipment (SA Instruments Inc., was a direct cardiomyocyte effect [7,9]. That there are dif- Stony Brook, NY 11790). Mice on the sled were then ferences between the Sgcd−/− and mdx mice has also re- placed on a bed holding the nose cone for anaesthesia cently been highlighted by a study showing marked delivery and then all of this slid into a 39 mm diameter hemodynamicdifferencesinresponsetoβ-blockers[10]. quadrature birdcage volume coil (Rapid Biomedical Manganese-enhanced cardiovascular magnetic reson- GmbH). Images were acquired on a 7 Tesla horizontal ance (MECMR) uses 2 properties of the manganese ion bore microimaging system equipped with a 12-cm microi- to allow in-vivo assessment of calcium influx [11]. Man- maging gradient insert (maximum gradient 40 gauss/cm) ganese enters cardiomyocytes through calcium channels, (Varian Inc., Palo Alto, CA, USA). Following power cali- and is also a T contrast agent with CMR. Thus, bration and global shimming a series of four pilot trans- 1 increased calcium influx with dobutamine increases con- verse images were acquired over the heart. Single slice trast-enhancement, and decreased influx with the cal- coronalandsagittalimageswerethenobtainedinorderto cium channel blocker diltiazem reduces contrast. We view the apex and mitral valve planes. These images were used MECMR to test the hypothesis that in-vivo calcium usedtoplanforthetrueshortaxisplane[14].Tomeasure influx in muscular dystrophy cardiomyopathy mice is left ventricular function, contiguous short axis slices were increased at an early stage in the development of the acquired to cover the entire left ventricle using a spoiled cardiomyopathy and so is an important factor in disease gradient-echo cine sequence (TR=5 ms, TE=1.42 ms, flip progression. To test this hypothesis we studied in-vivo left angle 15°, FOV 30×30 mm, data matrix 128×128, 1 mm ventricular function, and MECMR in Sgcd−/− and mdx slice thickness, max. of 10 slices depending on heart size, mice, determining the roles of ageing, L-type calcium 4averages).ImageswereECGtriggeredtotheRwavewith channelinhibitionandheartrateinthealteredmanganese acinedelayof15msandtypically30phaseswereacquired contrastenhancementpatternofthesemodels. distributed through the cardiac cycle (depending on HR). Images werezero-filled to a matrix size of 256×256. Scans Methods were converted to matfiles (using a matlab script kindly Animals: Two separate age groups of male mice were provided by Dr Johannes Riegler, University College used in this study. C57BL/10ScSnOlaHsd (wild type, London, UK) and analysed using the freely available ana- WT, Harlan Laboratories, Indianapolis, USA) and mdx lysissoftwareSegmentv1.8(http://segment.heiberg.se)[15] mice (C57BL/10ScSn-mdx/J, Jackson, Maine USA) were to measure left ventricular mass and the LV functional scanned at ages 24 and 40 weeks, and Sgcd−/− mice parameters – end-systolic and end-diastolic volumes, were scanned at 16 and 32 weeks (on C57Bl/6 back- strokevolume,ejectionfractionandcardiacoutput. ground, a kind gift from Dr Kevin Campbell, University ofIowa).Theseageswerechosen basedonpreviousdata ManganeseenhancedCMR(MECMR) reflectingthe earlier development ofthe cardiomyopathy For the manganese contrast enhancement, 60 mM man- in the Sgcd−/− compared to the mdx mice [12,13]. ganese chloride (Sigma-Aldrich 244589) was given by Numbersofmice inthe variousexperimentsaredetailed intravenous infusion through the tail vein cannula at a in the table and figure legends. The investigation con- flow-rate of 0.6 ml/hour, flow time adjusted according to forms with Directive 2010/63/EU of the European Par- weight to give a total dose of 190 nmol/g body weight. liament and was performed under the terms of the For a30 g mouse, this would result in a 9.5 minute infu- Animals (Scientific Procedures) Act 1986, authorized by sion. Gradient echo short axis images at the level of the the Home Secretary, Home Office UK. The Sgcd−/− papillary muscles (T weighted parameters: TR=35 ms, 1 mice were compared with the 8 week older C57/BL10 TE=3.5 ms, flip angle 60°, FOV 30 mm × 30 mm, data mice as controls, as preliminary data showed no differ- matrix128×128,1mmslicethickness,6averages)were ences in any measure of left ventricular function or taken. Four baseline images were acquired in order to manganese uptake between 16 and 24 week old C57/ average any variations due to changes in TR as a result BL10mice (datanot shown). of fluctuations in heart rate and then at 5 minute inter- vals for50 minutes duringandafter manganeseinfusion. CMR A relative increase in T weighted contrast indicates 1 Mice were anaesthetized using 5% isofluorane and an- increased manganese uptake (Figure 1). Images acquired aesthesia maintained at 1.5% in oxygen with a flow rate from each timepoint were extracted using a Python Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page3of8 http://jcmr-online.com/content/15/1/4 test differences amongst groups comparing an average value of steady state manganese contrast enhancement, and MR functional data. Post-hoc testing was performed with the Scheffe′ test. Single comparisons were made with Student’s t-tests. Data are expressed as mean ± standard error ofthemean. Results MRhaemodynamics:Leftventricularhypertrophyinolder Sgcd−/−andmdxmice,increasedheartratesandcardiac indexinSgcd−/−mice,andreducedstrokevolumein mdxmice Age had significant effects onhaemodynamics (ANOVA, all 3 groups combined), with significant increases in end-diastolic volume (P<0.01), end-systolic volume, and stroke volume (both P<0.05) (data not shown). As there Figure1Representativefigureshowingsingleexampleof manganesecontrastenhancementexperiment,with were significant differences in body weights, left ven- superimposedimagesshowingclearincreaseinmyocardial tricular mass, volume measurements and cardiac output contrastfollowingmanganeseinfusion. are indexed to body weight (i.e. cardiac index), and with that changes in volumes were no longer significant script (kindly written by Dr Conor Lawless, Newcastle (Table 1). Sgcd−/− mice had lower body weights, higher University), opened in Image J (http://rsb.info.nih.gov/ij/) heart rates, increased left ventricular mass index at the andconvertedtoastackusingthestackbuilderplugin.On older age, normal volumes, and increased cardiac index the first image an area of interest was drawn to fit inside at both ages. The increased cardiac index was a result of the myocardium and average signal intensity measured. the higher heart rate, as stroke volume index was not Minor adjustments of this drawn region were made for significantly different to WT mice. The mdx mice had subsequentimagesinthestackandtheincreaseinmyocar- significant left ventricular hypertrophy in the older age dial contrast enhancement expressed as a percentage in- group (though left ventricular mass index did not actu- creasefromtheaverageofthefourbaselineimages(which ally change in these mice with age, rather it was showedlittleornovariation). decreased in older WT mice), and reduced stroke vol- ume index when considering both age groups combined Pharmaceuticalmodificationofmanganesecontrast compared to WT. The mdx mice also had significantly enhancement lower ejection fractions compared to the Sgcd−/− mice. The L-type calcium channel antagonist diltiazem Thus, there were markedly different haemodynamic char- (5–10 mg/kg body weight i.p., 10 mg/kg being maximal acteristics in the 2 muscular dystrophy mice models. tolerated dose, Sigma Chemical Co., St Louis, MO) Whereas both had left ventricular hypertrophy at older was given separately to subgroups of the younger mice. ages when compared to older WT, there was a hyperdy- The hyperpolarization-activated cyclic nucleotide-gated namic circulation in the Sgcd−/− mice with increased car- (HCN)channelinhibitorZD7288(0.3mg/kgbodyweight diac index, and left ventricular systolic dysfunction with i.p., Sigma Chemical Co., St Louis, MO) was also given to reduced stroke volume in the mdx mice. Average surface separate groups to study the effects of selective heart rate temperatures measured during the scans were not signifi- reduction on manganese contrast enhancement [16,17]. cantlydifferentbetween thegroups (WT: 34.3±0.3°C, mdx FortheZD7288experimentswealsoincludeda2.5minute 33.5±0.4°CandSgcd−/−34.3±0.3°C(ANOVAp=NS). scanaswewereparticularlyinterestedintheearlykinetics of manganese uptake related to heart rate. These medica- MECMR:Slowerkineticsofmanganeseuptakeinallolder tionsweregivenpriortoplacingtheanimalinthescanner mice,andincreasedcontrastenhancementinyounger which was approximately 30–40 minutes before the man- Sgcd−/−andmdxmice ganeseinfusion. Contrast-enhancementwassignificantlyslowerinallolder mousegroupscomparedtoyoungermice(Figures2Aand Statistics B, P<0.05, time*age interaction, repeated measures To test effects of time and age on manganese-contrast ANOVA combining both age groups and all 3 groups). enhancement, repeated measures of analysis of variance For instance, in older WT mice contrast-enhancement at was used combining data from young and old groups. 5 minutes was 29±5% compared with 53±5% in younger Within each age group, analysis of variance was used to WT mice. This analysis also showed that when Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page4of8 http://jcmr-online.com/content/15/1/4 Table1Haemodynamicsinyoungandoldermice YOUNG OLD WT Mdx Sgcd−/− WT Mdx Sgcd−/− N 11 10 10 7 9 13 Bodyweight,g 33.3±0.9* 35.8±1.0** 28.8±1.0 40.5±1.2** 37.1±1.1 32.9±0.9 Heartrate,bpm 390±13** 419±14 480±14 384±16** 427±15 483±12 LVmassindex,(×10-3) 3.03±0.12 3.57±0.13 3.58±0.13 2.80±0.14** 3.56±0.13+ 3.86±0.11 EDVindex,μl/g 1.97±0.11 1.72±0.11 2.06±0.11 1.93±0.14 1.78±0.12 1.94±0.10 ESVindex,μl/g 0.70±0.07 0.68±0.08 0.67±0.08 0.72±0.09 0.74±0.08 0.69±0.07 Strokevolumeindex,μl/g 1.28±0.06 1.03±0.06**/† 1.38±0.06 1.21±0.07 1.04±0.06† 1.25±0.05 Ejectionfraction,% 65±2 61±2†† 68±2 63±3 60±2†† 65±2 Cardiacindex,ml/min/g 0.50±0.03** 0.43±0.03** 0.67±0.03 0.46±0.03# 0.44±0.03** 0.60±0.03 LV:leftventricle;EDV:end-diastolicvolume;ESV,end-systolicvolume. *P<0.01vsolderWT. **P<0.01vsSgcd−/−withinsameagegroup. +P<0.05vsWTwithinsameagegroup. #P=0.06vsSgcd−/−withinsameagegroup. †P<0.01ANOVAvsWTandSgcd−/−bothagescombined. ††P<0.05ANOVAvsSgcd−/−bothagescombined. consideringbothagestogethercontrastenhancementwas Sgcd−/− mice (6%, P=NS). A higher dose of diltiazem significantly elevated in the Sgcd−/− mice relative to con- (10 mg/kg) did produce significant reductions in contrast trols (P<0.05 post hoc Scheffe test), and this was of bor- enhancement in Sgcd−/− mice (21%, P<0.05), indicating derline significance for the mdx mice (P=0.08). To study that the L-type calcium channels were partially resistant contrast-enhancement within the 2 age groups, a mid intheSgcd−/−mice.Consistentwiththevariablesensitiv- point value of contrast enhancement was defined as the itytoL-typecalciumchannelblockade,diltiazem5mg/kg mean contrast enhancement of the steady state period of significantlyreducedheartratesintheWTandmdxmice, 10 to 25 minutes after start of the manganese infusion, but not in the Sgcd−/− mice, though 10 mg/kg did pro- with5minuteintervalscans.Intheoldermice,midpoint duce significant reductions in the Sgcd−/− mice contrast enhancement was borderline increased in the (Figure3B). Sgcd−/− compared toWTmice(P=0.07,posthocScheffe test), and not significantly different in the mdx mice Theroleofheartrateinmanganesecontrast (Figure 2C). In the younger mice, mid point contrast enhancement enhancement was significantly increased in both the Therewasincreasedcontrast-enhancementintheSgcd−/− Sgcd−/− and mdx compared to WT mice (both P<0.05, mice which accompanied a significantly higher heart rate posthocScheffetest).AstheSgcd−/−micewereonadif- comparedtoWTmice(Table1),andthusthemechanism ferentstrainbackgroundtotheC57Bl/10controlsweper- of this increased contrast-enhancement could be due to formed initial experiments to determine if there was a more heart beats and action potentials transmitting Mn2+ strain difference between C57Bl/10 and C57Bl/6 mice. In into the cell, though could also be related to a cellular these experiments the mid point contrast enhancement channel defect with increased Mn2+ entry into the myo- was 50±6% in C57Bl/10 (N=5) and 50±10.0% in C57Bl/6 cyte per action potential. To clarify this issue we used the mice (N=3, p=NS) indicating that there was no strain HCN channel inhibitor ZD 7288 to selectively reduce effect. heart rate in all 3 groups of younger mice. ZD 7288 sig- nificantly reduced contrast enhancement in all 3 groups Pharmaceuticalmodificationofcalciumchannels: of mice, and this was associated with significant reduc- ResistancetoL-typecalciumchannelblockadeinyoung tions in heart rate (Figure 4A and B). This does suggest Sgcd−/−mice in general that the manganese contrast enhancement sig- We concentrated on the younger mice for the pharma- nal is sensitive to heart rate, and care must therefore be ceuticalstudiesastheseweretheageswherethemostsig- taken when comparing mouse models with different heart nificantincreasesincontrastenhancementwereseen.The rates with this technique. However, when comparing the L-type calcium channel blocker diltiazem (5 mg/kg i.p.) time plots of contrast enhancement and heart rates in significantlyreducedcontrastenhancement(Figure3A)in the WTand Sgcd−/− mice (Figure 4C and D) we see that WT (21%, P<0.05) and to a greater extent in mdx mice at a very early stage in the increase in contrast enhance- (38%, P<0.001), though had no significant effects in the ment (2.5 and 5 minutes) when heart rates of both Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page5of8 http://jcmr-online.com/content/15/1/4 Figure3EffectsofL-typeCalciumChannelBlockerDiltiazem onManganeseContrastEnhancement.A.Midpointcontrast enhancementinyoungermicewithnopharmacologicaltreatment (leftcolumn),showingsignificanthigherlevelsofmidpointcontrast enhancementinmdxandSgcd−/−vsWTmice(+P<0.05versusWT, asinFigure2C).Diltiazem5mgproducedsignificantreductionsin contrastenhancementinmdx(N=7)andWT(N=6)versusno treatment,thoughnotfortheSgcd−/−mice(N=6).Diltiazem10mg producedasignificantreductionincontrastenhancementinthe Sgcd−/−mice(N=9);(+P<0.05versusWT;*P<0.05and**P<0.01 versusuntreated,withinsamestrain).B.Effectsofdiltiazemonheart rates.Diltiazem(5mg)significantlyreducedheartratesinWTandin mdxmice,thoughnotinSgcd−/−mice,asimilareffectasseenwith manganesecontrastenhancement.Higherdosesofdiltiazem (10mg)significantlyreducedheartratesintheSgcd−/−mice. (*P<0.05versuswithoutdiltiazem). Figure2EffectsofAgeingonManganeseContrastEnhancement. Manganesecontrastenhancementinoldermice(A)andyoung groups of mice are very similar that there was still a mice(B).Thekineticsofmanganesecontrastenhancementare slowerintheoldermicecomparedtoyoungermice(P<0.05 marked increase in contrast-enhancement in the Sgcd−/− repeatedmeasuresANOVA).C.Midpointcontrastenhancementin mice compared to wild type. Thus, while contrast- olderandyoungermice.Therewasaborderlineincreaseincontrast enhancement is sensitive to heart rate, by reducing the enhancementintheolderSgcd−/−mice(#P=0.07versusWT)andin heart rate in the Sgcd−/− mice to WT levels we can see theyoungermicecontrastenhancementwassignificantlyelevated that there is clearly a component of increased cellular up- inbothSgcd−/−andmdxmice(+P<0.05versusWT).Forthe youngermiceNasareinTable1,intheoldermiceWTN=9,mdx take of Mn2+ per action potential. The pattern of early N=10,andSgcd−/−miceN=15(assomeoldermicedidnothave increased contrast enhancement was not however seen functionaldata). in the mdx mice. For instance, at 2.5 minutes with simi- lar heart rates to WT mice contrast enhancement was 22±5% in the mdx mice compared to 17±6% in the WT mice (p=NS), so this illustrates a different pattern to the Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page6of8 http://jcmr-online.com/content/15/1/4 Figure4EffectofHeartRateReductiononManganeseContrastEnhancement.AandB.TheHCNchannelinhibitorZD7288significantly reducedmidpointcontrastenhancementinallmousegroups(**P<0.01versuswithoutZD7288),andthiswasaccompaniedbysignificant reductionsinheartratealsoinallgroups(**P<0.01versusheartratepreZD7288)(WTN=8,mdxN=9,Sgcd−/−N=10).CandD.Whenthe timecourseofmanganesecontrastenhancementandheartrateinthewildtypeandSgcd−/−miceisexaminedwecanseethattheZD7288 reducesheartrateintheSgcd−/−micetothesamelevelaswildtypemicefromthetimeofstartingthemanganeseinfusion,thoughduringthe first5minutesthereisstillasignificantlyhigherlevelofmanganesecontrastenhancementintheSgcd−/−micecomparedtoWT(**P<0.01).This indicatesthatwhereasheartrateisanimportantfactorintheextentofmanganesecontrastenhancement,intheSgcd−/−micethereisatleast somecomponentofincreasedcellularuptakeofmanganeseperheartbeatcomparedtoWT. Sgcd−/− mice, and potentially different mechanism of the increased contrast enhancement, and selective heart abnormal contrast enhancement. ratereductionreducescontrastenhancementinallgroups. Nevertheless, it is clear in the Sgcd−/− mice that when Discussion heart rates are reduced to wild type levels, there is still In muscular dystrophy cardiomyopathy at an early stage increased manganese contrast enhancement indicating a inthedevelopmentofthe cardiomyopathybeforesignifi- primary cellular defect in calcium influx. This increase in cant left ventricular hypertrophy in both the mdx and early contrast enhancement after heart rate reduction is Sgcd−/− mouse models, in-vivo calcium influx is notseenwiththemdxmice. increased (as determined by manganese contrast en- hancement). However, there are clear differences in both L-typecalciumchannelsinmusculardystrophy left ventricular function and myocardial calcium influx cardiomyopathy betweenthe2models.Themdxmousehasleftventricu- We were interested in L-type calcium channel blockers lar systolic dysfunction with a reduction in stroke vol- for 2 reasons – 1) they can reduce manganese contrast ume, whereas the Sgcd−/− mice have increased heart enhancement [11], and 2) have differential effects in the rates, cardiac index and so a hyperdynamic circulation. mdx and Sgcd−/− mice [8]. It is known that intracellular Ejection fractions are lower in the mdx compared to the calcium is increased in muscular dystrophy cardiomyop- Sgcd−/− mice. These are also differences in the responses athy [7,18]. Cohn et al. [8] have shown that the L-type to L-type calcium channel blockade in that there is a rela- calcium channel blocker verapamil had significant bene- tive resistance in the Sgcd−/− mice though mdx mice ex- ficial effects in the Sgcd−/− mice on troponin I levels hibit a similar response to wild type mice. As heart rate is and cardiac histology, though not in the mdx mice. To increasedintheSgcd−/−mice,thisispotentiallyacauseof reconcile the findings in this study and our findings it is Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page7of8 http://jcmr-online.com/content/15/1/4 necessary to examine doses used. The doses used in Highertemperatures wouldhavelikelyresulted inhigher Cohn et al. compared to the present one are different heart ratesandthis mayalter manganeseuptake rates. when corresponding human doses calculated by weight are examined, though a consistent theme is that high Age-relatedchangesinmyocardialcalciuminflux doses are required. The doses of diltiazem in the current Isenberg et al. [22] have shown that in aged mice cal- study of 5–10 mg/kg would equal 350–700 mg in a cium transients peak late and decay slowly. Salameh 70 kg human, the upper limit of a normal human dose et al. [23] have shown that the L-type calcium (I ) Ca.L being 240 mg. The dose of verapamil used by Cohn current is abnormal in aging rabbit hearts with the I Ca.L et al. was 3.5 mg/day, which would be approximately density normalised to cell volume significantly reduced, 35 fold higher than an appropriate human dose. One maximum conductance also significantly decreased and possible consistent explanation is that only higher steady state inactivation shifted to more positive poten- doses of L-type calcium channel antagonists are effect- tials in aged hearts. However, expression of the α sub- 1c ive in the Sgcd−/− mice, as we only show responses to unit of the L-type channel, the SERCA2a-ATPase, and higher doses of diltiazem. There are strain differences the Na+/Ca2+ exchanger did not differ significantly be- in the backgrounds of the wild type and mdx (both tween the two age groups. Direct comparison of cellular C57Bl/10) versus the Sgcd−/− mice (C57Bl/6). Though calcium handling and MECMR would be very inform- we could find no differences between Bl/10 and Bl/6 ative in studying age-related changes in calcium influx. mice in terms of manganese uptake, we cannot rule Ouryoung andoldmice wereseparategroups andinfu- out some strain effect in the response to L-type cal- ture, serial MECMR studies within the same mouse will cium channel blockade. alsobeimportant. Roleofheartrateinmanganesecontrastenhancement Leftventricularfunctioninmousemodelsofmuscular When comparing models with different heart rates, it dystrophycardiomyopathy may be difficult to determine whether a difference in We have previously shown that there are differences in manganese contrast enhancement is due to the function between the mdx and Sgcd−/− mouse models increased heart rate resulting in more action potentials using the conductance catheter [10], and these results over the period of the manganese infusion or whether are very consistent despite the very different techniques, there is an underlying cellular defect with an altered cal- though adding information about left ventricular mass cium influx per action potential [19]. To determine and calcium influx. Townsend et al. [24] have compared whether the increased heart rate in the Sgcd−/− mice these mouse models and also found distinct differences accounts for the increased manganese contrast enhance- (at 6 – 8 months of age). Isolated myocytes from the ment we have used the HCN channel inhibitor ZD 7288 mdx mice show reduced compliance and are susceptible which inhibits the I channel producing a selective re- to terminal contracture, whereas the Sgcd−/− mice had f duction in heart rate [16,17]. These studies clearly show normal compliance. There was increased fibrosis in the that at matched heart rates, the Sgcd−/− mice have Sgcd−/− hearts, though not in the mdx. We have also increased manganese contrast enhancement compared shown that mdx mice exhibit improved hemodynamics to wild type, indicating a primary cellular defect in cal- with 8 weeks of β-blocker treatment though there is sig- ciuminflux.Theseexperimentsalsoshowclearlytheim- nificant deterioration in the Sgcd−/− mice with reduced portant role that heart rate plays in manganese contrast heart rate, cardiac output and impaired active relaxation enhancement, so that for instance, in our experiments [10]. Despite this information a specific molecular path- with diltiazem it is reasonable to assume that some of way bywhichthesedifferencesoccurisstill unclear. the reduction in contrast enhancement is due to a re- duction in heart rate. Of note, a small amount of cal- Conclusionsandclinicalrelevance cium may enter cardiac myocytes through the I channel We have shown at an early stage in the development of f (0.5% of the current from the HCN2 channel) [20], muscular dystrophy cardiomyopathy that in-vivo calcium thoughthissmallamountisunlikelytohavesignificantly influx is increased. Increased calcium influx and left ven- effected our results. Furthermore, as the mdx mice do tricularhypertrophyareseeninbothmodels,thoughother not have significantly different heart rates compared to importanthaemodynamicandpharmacologicaldifferences wild type mice the increase in manganese contrast en- are apparent, so that all these factors need to be consid- hancement will be due to a primary cellular defect in ered together when assessing mechanisms of the cardio- calcium influx. Surface temperatures of the mice were myopathy and response to therapies. A limitation of below physiological levels during the scans, and so heart these in-vivo techniques is that it is difficult to say defini- rates were also low. Surface temperatures are approxi- tively if there are specific abnormalities in channels such mately 1°C lower than core body temperature [21]. as the L-type calcium channel in these models. Thus, the Greallyetal.JournalofCardiovascularMagneticResonance2013,15:4 Page8of8 http://jcmr-online.com/content/15/1/4 future utility of these non-invasive in-vivo techniques will 12. QuinlanJG,HahnHS,WongBL,LorenzJN,WenischAS,LevinLS.Evolution likely be in serially assessing responses to novel preclin- ofthemdxmousecardiomyopathy:physiologicalandmorphological findings.NeuromusculDisord2004;14:491–6. ical treatments. 13. Coral-VazquezR,CohnRD,MooreSA,HillJA,WeissRM,DavissonRL,Straub V,BarresiR,BansalD,HrstkaRF,WilliamsonR,CampbellKP.Disruptionof Competinginterests thesarcoglycan–sarcospancomplexinvascularsmoothmuscle:anovel Theauthorsdeclaredthattheyhavenocompetinginterests. mechanismforcardiomyopathyandmusculardystrophy.Cell1999; 98:465–474. Authors’contributions 14. SchneiderJE,WiesmannF,LygateCA,NeubauerS.Howtoperforman G:performedscans,analyseddata,wrotepaper;D:developedMRtechnique, accurateassessmentofcardiacfunctioninmiceusinghigh-resolution performedscans,analyseddata,contributedtowritingpaper,B:performed magneticresonanceimaging.JCardiovascMagnReson2006;85:693–701. scans,histologicalstudies,contributedtowritingpaper:L:analyseddata, 15. 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